feat(mamba): add Mamba2 implementation

Add initial project structure including core Mamba2 logic, entry point, and uv-based dependency management.
2026-01-21 12:54:49 +08:00
commit c58a73ae26
8 changed files with 2151 additions and 0 deletions
--- a/.gitignore
+++ b/.gitignore
@@ -0,0 +1,10 @@
 # Python-generated files
 __pycache__/
 *.py[oc]
 build/
 dist/
 wheels/
 *.egg-info
 # Virtual environments
 .venv
--- a/.python-version
+++ b/.python-version
@@ -0,0 +1 @@
 3.12
--- a/README.md
+++ b/README.md
--- a/as_mamba.py
+++ b/as_mamba.py
@@ -0,0 +1,511 @@
 from __future__ import annotations
 from dataclasses import asdict, dataclass
 from pathlib import Path
 from typing import Optional
 import matplotlib
 matplotlib.use("Agg")
 import numpy as np
 import torch
 import torch.nn.functional as F
 from matplotlib import pyplot as plt
 from mpl_toolkits.mplot3d import Axes3D  # noqa: F401
 from torch import Tensor, nn
 from mamba2_minimal import InferenceCache, Mamba2, Mamba2Config, RMSNorm
@dataclass
 class TrainConfig:
    seed: int = 42
    device: str = "cuda"
    batch_size: int = 128
    steps_per_epoch: int = 50
    epochs: int = 60
    warmup_epochs: int = 15
    seq_len: int = 20
    lr: float = 1e-3
    weight_decay: float = 1e-2
    dt_min: float = 1e-3
    dt_max: float = 0.06
    lambda_flow: float = 1.0
    lambda_pos: float = 1.0
    lambda_nfe: float = 0.05
    radius_min: float = 0.6
    radius_max: float = 1.4
    center_min: float = -6.0
    center_max: float = 6.0
    center_distance_min: float = 6.0
    d_model: int = 128
    n_layer: int = 4
    d_state: int = 64
    d_conv: int = 4
    expand: int = 2
    headdim: int = 32
    chunk_size: int = 1
    use_residual: bool = False
    output_dir: str = "outputs"
    project: str = "as-mamba"
    run_name: str = "sphere-to-sphere"
    val_every: int = 200
    val_samples: int = 256
    val_plot_samples: int = 16
    val_max_steps: int = 100
 class Mamba2Backbone(nn.Module):
    def __init__(self, args: Mamba2Config, use_residual: bool = True) -> None:
        super().__init__()
        self.args = args
        self.use_residual = use_residual
        self.layers = nn.ModuleList(
            [
                nn.ModuleDict(
                    dict(
                        mixer=Mamba2(args),
                        norm=RMSNorm(args.d_model),
                    )
                )
                for _ in range(args.n_layer)
            ]
        )
        self.norm_f = RMSNorm(args.d_model)
    def forward(
        self, x: Tensor, h: Optional[list[InferenceCache]] = None
    ) -> tuple[Tensor, list[InferenceCache]]:
        if h is None:
            h = [None for _ in range(self.args.n_layer)]
        for i, layer in enumerate(self.layers):
            y, h[i] = layer["mixer"](layer["norm"](x), h[i])
            x = x + y if self.use_residual else y
        x = self.norm_f(x)
        return x, h
 class ASMamba(nn.Module):
    def __init__(self, cfg: TrainConfig) -> None:
        super().__init__()
        self.cfg = cfg
        self.dt_min = float(cfg.dt_min)
        self.dt_max = float(cfg.dt_max)
        args = Mamba2Config(
            d_model=cfg.d_model,
            n_layer=cfg.n_layer,
            d_state=cfg.d_state,
            d_conv=cfg.d_conv,
            expand=cfg.expand,
            headdim=cfg.headdim,
            chunk_size=cfg.chunk_size,
        )
        self.backbone = Mamba2Backbone(args, use_residual=cfg.use_residual)
        self.input_proj = nn.Linear(3, cfg.d_model)
        self.delta_head = nn.Linear(cfg.d_model, 3)
        self.dt_head = nn.Sequential(
            nn.Linear(cfg.d_model, cfg.d_model),
            nn.SiLU(),
            nn.Linear(cfg.d_model, 1),
        )
    def forward(
        self, x: Tensor, h: Optional[list[InferenceCache]] = None
    ) -> tuple[Tensor, Tensor, list[InferenceCache]]:
        x_proj = self.input_proj(x)
        feats, h = self.backbone(x_proj, h)
        delta = self.delta_head(feats)
        dt_raw = self.dt_head(feats).squeeze(-1)
        dt = torch.clamp(F.softplus(dt_raw), min=self.dt_min, max=self.dt_max)
        return delta, dt, h
    def step(
        self, x: Tensor, h: list[InferenceCache]
    ) -> tuple[Tensor, Tensor, list[InferenceCache]]:
        delta, dt, h = self.forward(x.unsqueeze(1), h)
        return delta[:, 0, :], dt[:, 0], h
    def init_cache(self, batch_size: int, device: torch.device) -> list[InferenceCache]:
        return [
            InferenceCache.alloc(batch_size, self.backbone.args, device=device)
            for _ in range(self.backbone.args.n_layer)
        ]
 class SwanLogger:
    def __init__(self, cfg: TrainConfig) -> None:
        self.enabled = False
        self._swan = None
        self._run = None
        try:
            import swanlab  # type: ignore
            self._swan = swanlab
            self._run = self._swan.init(
                project=cfg.project,
                experiment_name=cfg.run_name,
                config=asdict(cfg),
            )
            self.enabled = True
        except Exception:
            self.enabled = False
    def log(self, metrics: dict, step: int | None = None) -> None:
        if not self.enabled:
            return
        target = self._run if self._run is not None else self._swan
        if step is None:
            target.log(metrics)
            return
        try:
            target.log(metrics, step=step)
        except TypeError:
            payload = dict(metrics)
            payload["step"] = step
            target.log(payload)
    def log_image(
        self, key: str, image_path: Path, caption: str | None = None, step: int | None = None
    ) -> None:
        if not self.enabled:
            return
        image = self._swan.Image(str(image_path), caption=caption)
        self.log({key: image}, step=step)
    def finish(self) -> None:
        if not self.enabled:
            return
        finish = None
        if self._run is not None:
            finish = getattr(self._run, "finish", None)
        if finish is None:
            finish = getattr(self._swan, "finish", None)
        if callable(finish):
            finish()
 def set_seed(seed: int) -> None:
    torch.manual_seed(seed)
    if torch.cuda.is_available():
        torch.cuda.manual_seed_all(seed)
 def sample_points_in_sphere(
    center: Tensor, radius: float, batch_size: int, device: torch.device
 ) -> Tensor:
    direction = torch.randn(batch_size, 3, device=device)
    direction = direction / (direction.norm(dim=-1, keepdim=True) + 1e-8)
    u = torch.rand(batch_size, 1, device=device)
    r = radius * torch.pow(u, 1.0 / 3.0)
    return center + direction * r
 def sample_sphere_params(cfg: TrainConfig, device: torch.device) -> tuple[Tensor, Tensor]:
    center_a = torch.empty(3, device=device).uniform_(cfg.center_min, cfg.center_max)
    center_b = torch.empty(3, device=device).uniform_(cfg.center_min, cfg.center_max)
    for _ in range(128):
        if torch.norm(center_a - center_b) >= cfg.center_distance_min:
            break
        center_b = torch.empty(3, device=device).uniform_(cfg.center_min, cfg.center_max)
    if torch.norm(center_a - center_b) < 1e-3:
        center_b = center_b + torch.tensor([cfg.center_distance_min, 0.0, 0.0], device=device)
    radius_a = float(torch.empty(1).uniform_(cfg.radius_min, cfg.radius_max).item())
    radius_b = float(torch.empty(1).uniform_(cfg.radius_min, cfg.radius_max).item())
    return (center_a, torch.tensor(radius_a, device=device)), (
        center_b,
        torch.tensor(radius_b, device=device),
    )
 def sample_batch(
    cfg: TrainConfig,
    sphere_a: tuple[Tensor, Tensor],
    sphere_b: tuple[Tensor, Tensor],
    device: torch.device,
 ) -> tuple[Tensor, Tensor, Tensor, Tensor]:
    center_a, radius_a = sphere_a
    center_b, radius_b = sphere_b
    x0 = sample_points_in_sphere(center_a, float(radius_a.item()), cfg.batch_size, device)
    x1 = sample_points_in_sphere(center_b, float(radius_b.item()), cfg.batch_size, device)
    v_gt = x1 - x0
    dt_fixed = 1.0 / cfg.seq_len
    t_seq = torch.arange(cfg.seq_len, device=device) * dt_fixed
    x_seq = x0[:, None, :] + t_seq[None, :, None] * v_gt[:, None, :]
    return x0, x1, x_seq, t_seq
 def compute_losses(
    delta: Tensor,
    dt: Tensor,
    x_seq: Tensor,
    x0: Tensor,
    v_gt: Tensor,
    t_seq: Tensor,
    cfg: TrainConfig,
 ) -> tuple[Tensor, Tensor, Tensor]:
    target_disp = v_gt[:, None, :] * dt.unsqueeze(-1)
    flow_loss = F.mse_loss(delta, target_disp)
    t_next = t_seq[None, :, None] + dt.unsqueeze(-1)
    t_next = torch.clamp(t_next, 0.0, 1.0)
    x_target = x0[:, None, :] + t_next * v_gt[:, None, :]
    x_next_pred = x_seq + delta
    pos_loss = F.mse_loss(x_next_pred, x_target)
    nfe_loss = (-torch.log(dt)).mean()
    return flow_loss, pos_loss, nfe_loss
 def validate(
    model: ASMamba,
    cfg: TrainConfig,
    sphere_a: tuple[Tensor, Tensor],
    sphere_b: tuple[Tensor, Tensor],
    device: torch.device,
    logger: SwanLogger,
    step: int,
 ) -> None:
    model.eval()
    center_b, radius_b = sphere_b
    with torch.no_grad():
        x0 = sample_points_in_sphere(
            sphere_a[0], float(sphere_a[1].item()), cfg.val_samples, device
        )
        traj = rollout_trajectory(model, x0, max_steps=cfg.val_max_steps)
    x_final = traj[:, -1, :]
    center_b_cpu = center_b.detach().cpu()
    radius_b_cpu = radius_b.detach().cpu()
    dist = torch.linalg.norm(x_final - center_b_cpu, dim=-1)
    inside = dist <= radius_b_cpu
    logger.log(
        {
            "val/inside_ratio": float(inside.float().mean().item()),
            "val/inside_count": float(inside.float().sum().item()),
            "val/final_dist_mean": float(dist.mean().item()),
            "val/final_dist_min": float(dist.min().item()),
            "val/final_dist_max": float(dist.max().item()),
        },
        step=step,
    )
    if cfg.val_plot_samples > 0:
        count = min(cfg.val_plot_samples, traj.shape[0])
        if count == 0:
            model.train()
            return
        indices = torch.linspace(0, traj.shape[0] - 1, steps=count).long()
        traj_plot = traj[indices]
        save_path = Path(cfg.output_dir) / f"val_traj_step_{step:06d}.png"
        plot_trajectories(
            traj_plot,
            sphere_a,
            sphere_b,
            save_path,
            title=f"Validation Trajectories (step {step})",
        )
        ratio = float(inside.float().mean().item())
        logger.log_image(
            "val/trajectory",
            save_path,
            caption=f"step {step} | inside_ratio={ratio:.3f}",
            step=step,
        )
    model.train()
 def train(cfg: TrainConfig) -> tuple[ASMamba, tuple[Tensor, Tensor], tuple[Tensor, Tensor]]:
    device = torch.device(cfg.device if torch.cuda.is_available() else "cpu")
    set_seed(cfg.seed)
    output_dir = Path(cfg.output_dir)
    output_dir.mkdir(parents=True, exist_ok=True)
    model = ASMamba(cfg).to(device)
    optimizer = torch.optim.AdamW(model.parameters(), lr=cfg.lr, weight_decay=cfg.weight_decay)
    logger = SwanLogger(cfg)
    sphere_a, sphere_b = sample_sphere_params(cfg, device)
    center_a, radius_a = sphere_a
    center_b, radius_b = sphere_b
    center_dist = torch.norm(center_a - center_b).item()
    logger.log(
        {
            "sphere_a/radius": float(radius_a.item()),
            "sphere_b/radius": float(radius_b.item()),
            "sphere_a/center_x": float(center_a[0].item()),
            "sphere_a/center_y": float(center_a[1].item()),
            "sphere_a/center_z": float(center_a[2].item()),
            "sphere_b/center_x": float(center_b[0].item()),
            "sphere_b/center_y": float(center_b[1].item()),
            "sphere_b/center_z": float(center_b[2].item()),
            "sphere/center_dist": float(center_dist),
        }
    )
    global_step = 0
    for epoch in range(cfg.epochs):
        warmup = epoch < cfg.warmup_epochs
        model.train()
        for p in model.dt_head.parameters():
            p.requires_grad = not warmup
        for _ in range(cfg.steps_per_epoch):
            x0, x1, x_seq, t_seq = sample_batch(cfg, sphere_a, sphere_b, device)
            v_gt = x1 - x0
            delta, dt, _ = model(x_seq)
            if warmup:
                dt = torch.full_like(dt, 1.0 / cfg.seq_len)
            flow_loss, pos_loss, nfe_loss = compute_losses(
                delta=delta,
                dt=dt,
                x_seq=x_seq,
                x0=x0,
                v_gt=v_gt,
                t_seq=t_seq,
                cfg=cfg,
            )
            loss = cfg.lambda_flow * flow_loss + cfg.lambda_pos * pos_loss
            if not warmup:
                loss = loss + cfg.lambda_nfe * nfe_loss
            optimizer.zero_grad(set_to_none=True)
            loss.backward()
            optimizer.step()
            if global_step % 10 == 0:
                logger.log(
                    {
                        "loss/total": float(loss.item()),
                        "loss/flow": float(flow_loss.item()),
                        "loss/pos": float(pos_loss.item()),
                        "loss/nfe": float(nfe_loss.item()),
                        "dt/mean": float(dt.mean().item()),
                        "dt/min": float(dt.min().item()),
                        "dt/max": float(dt.max().item()),
                        "stage": 0 if warmup else 1,
                    },
                    step=global_step,
                )
            if cfg.val_every > 0 and global_step > 0 and global_step % cfg.val_every == 0:
                validate(model, cfg, sphere_a, sphere_b, device, logger, global_step)
            global_step += 1
    logger.finish()
    return model, sphere_a, sphere_b
 def rollout_trajectory(
    model: ASMamba,
    x0: Tensor,
    max_steps: int = 100,
 ) -> Tensor:
    device = x0.device
    model.eval()
    h = model.init_cache(batch_size=x0.shape[0], device=device)
    x = x0
    total_time = torch.zeros(x0.shape[0], device=device)
    traj = [x0.detach().cpu()]
    with torch.no_grad():
        for _ in range(max_steps):
            delta, dt, h = model.step(x, h)
            dt = torch.clamp(dt, min=model.dt_min, max=model.dt_max)
            remaining = 1.0 - total_time
            overshoot = dt > remaining
            if overshoot.any():
                scale = (remaining / dt).unsqueeze(-1)
                delta = torch.where(overshoot.unsqueeze(-1), delta * scale, delta)
                dt = torch.where(overshoot, remaining, dt)
            x = x + delta
            total_time = total_time + dt
            traj.append(x.detach().cpu())
            if torch.all(total_time >= 1.0 - 1e-6):
                break
    return torch.stack(traj, dim=1)
 def sphere_wireframe(
    center: Tensor, radius: float, u_steps: int = 24, v_steps: int = 12
 ) -> tuple[np.ndarray, np.ndarray, np.ndarray]:
    center_np = center.detach().cpu().numpy()
    u = np.linspace(0, 2 * np.pi, u_steps)
    v = np.linspace(0, np.pi, v_steps)
    x = center_np[0] + radius * np.outer(np.cos(u), np.sin(v))
    y = center_np[1] + radius * np.outer(np.sin(u), np.sin(v))
    z = center_np[2] + radius * np.outer(np.ones_like(u), np.cos(v))
    return x, y, z
 def plot_trajectories(
    traj: Tensor,
    sphere_a: tuple[Tensor, Tensor],
    sphere_b: tuple[Tensor, Tensor],
    save_path: Path,
    title: str = "AS-Mamba Trajectories",
 ) -> None:
    traj = traj.detach().cpu()
    if traj.dim() == 2:
        traj = traj.unsqueeze(0)
    traj_np = traj.numpy()
    fig = plt.figure(figsize=(7, 6))
    ax = fig.add_subplot(111, projection="3d")
    for i in range(traj_np.shape[0]):
        ax.plot(
            traj_np[i, :, 0],
            traj_np[i, :, 1],
            traj_np[i, :, 2],
            color="green",
            alpha=0.6,
        )
    starts = traj_np[:, 0, :]
    ends = traj_np[:, -1, :]
    ax.scatter(starts[:, 0], starts[:, 1], starts[:, 2], color="blue", s=20, label="Start")
    ax.scatter(ends[:, 0], ends[:, 1], ends[:, 2], color="red", s=20, label="End")
    center_a, radius_a = sphere_a
    center_b, radius_b = sphere_b
    x_a, y_a, z_a = sphere_wireframe(center_a, float(radius_a.item()))
    x_b, y_b, z_b = sphere_wireframe(center_b, float(radius_b.item()))
    ax.plot_wireframe(x_a, y_a, z_a, color="blue", alpha=0.15, linewidth=0.5)
    ax.plot_wireframe(x_b, y_b, z_b, color="red", alpha=0.15, linewidth=0.5)
    ax.set_title(title)
    ax.set_xlabel("X")
    ax.set_ylabel("Y")
    ax.set_zlabel("Z")
    ax.legend(loc="best")
    fig.tight_layout()
    fig.savefig(save_path, dpi=160)
    plt.close(fig)
 def run_training_and_plot(cfg: TrainConfig) -> Path:
    model, sphere_a, sphere_b = train(cfg)
    device = next(model.parameters()).device
    plot_samples = max(1, cfg.val_plot_samples)
    x0 = sample_points_in_sphere(
        sphere_a[0], float(sphere_a[1].item()), plot_samples, device
    )
    traj = rollout_trajectory(model, x0, max_steps=cfg.val_max_steps)
    output_dir = Path(cfg.output_dir)
    save_path = output_dir / "as_mamba_trajectory.png"
    plot_trajectories(traj, sphere_a, sphere_b, save_path)
    return save_path
--- a/main.py
+++ b/main.py
@@ -0,0 +1,43 @@
 import argparse
 from as_mamba import TrainConfig, run_training_and_plot
 def build_parser() -> argparse.ArgumentParser:
    parser = argparse.ArgumentParser(description="Train AS-Mamba on sphere-to-sphere flow.")
    parser.add_argument("--epochs", type=int, default=None)
    parser.add_argument("--warmup-epochs", type=int, default=None)
    parser.add_argument("--batch-size", type=int, default=None)
    parser.add_argument("--steps-per-epoch", type=int, default=None)
    parser.add_argument("--seq-len", type=int, default=None)
    parser.add_argument("--lr", type=float, default=None)
    parser.add_argument("--device", type=str, default=None)
    parser.add_argument("--output-dir", type=str, default=None)
    parser.add_argument("--project", type=str, default=None)
    parser.add_argument("--run-name", type=str, default=None)
    parser.add_argument("--val-every", type=int, default=None)
    parser.add_argument("--val-samples", type=int, default=None)
    parser.add_argument("--val-plot-samples", type=int, default=None)
    parser.add_argument("--val-max-steps", type=int, default=None)
    parser.add_argument("--center-min", type=float, default=None)
    parser.add_argument("--center-max", type=float, default=None)
    parser.add_argument("--center-distance-min", type=float, default=None)
    parser.add_argument("--use-residual", action="store_true")
    return parser
 def main() -> None:
    parser = build_parser()
    args = parser.parse_args()
    cfg = TrainConfig()
    for key, value in vars(args).items():
        if value is not None:
            setattr(cfg, key.replace("-", "_"), value)
    plot_path = run_training_and_plot(cfg)
    print(f"Saved trajectory plot to {plot_path}")
 if __name__ == "__main__":
    main()
--- a/mamba2_minimal.py
+++ b/mamba2_minimal.py
@@ -0,0 +1,246 @@
 """
 mamba2-minimal
 ==============
 Minimal Mamba-2 implementation for sequence modeling.
 Reference: https://arxiv.org/abs/2405.21060
 """
 from __future__ import annotations
 import math
 from dataclasses import dataclass
 from typing import NamedTuple, TypeAlias
 import torch
 import torch.nn.functional as F
 from einops import rearrange, repeat
 from torch import Tensor, nn
 Device: TypeAlias = str | torch.device | None
@dataclass
 class Mamba2Config:
    d_model: int
    n_layer: int = 4
    d_state: int = 64
    d_conv: int = 4
    expand: int = 2
    headdim: int = 32
    chunk_size: int = 1
    def __post_init__(self) -> None:
        self.d_inner = self.expand * self.d_model
        if self.d_inner % self.headdim != 0:
            raise ValueError("d_inner must be divisible by headdim")
        self.nheads = self.d_inner // self.headdim
 class InferenceCache(NamedTuple):
    conv_state: Tensor
    ssm_state: Tensor
    @staticmethod
    def alloc(batch_size: int, args: Mamba2Config, device: Device = None) -> "InferenceCache":
        return InferenceCache(
            torch.zeros(
                batch_size, args.d_inner + 2 * args.d_state, args.d_conv, device=device
            ),
            torch.zeros(
                batch_size, args.nheads, args.headdim, args.d_state, device=device
            ),
        )
 class Mamba2(nn.Module):
    def __init__(self, args: Mamba2Config, device: Device = None) -> None:
        super().__init__()
        self.args = args
        self.device = device
        d_in_proj = 2 * args.d_inner + 2 * args.d_state + args.nheads
        self.in_proj = nn.Linear(args.d_model, d_in_proj, bias=False, device=device)
        conv_dim = args.d_inner + 2 * args.d_state
        self.conv1d = nn.Conv1d(
            in_channels=conv_dim,
            out_channels=conv_dim,
            kernel_size=args.d_conv,
            groups=conv_dim,
            padding=args.d_conv - 1,
            device=device,
        )
        self.dt_bias = nn.Parameter(torch.empty(args.nheads, device=device))
        self.A_log = nn.Parameter(torch.empty(args.nheads, device=device))
        self.D = nn.Parameter(torch.empty(args.nheads, device=device))
        self.norm = RMSNorm(args.d_inner, device=device)
        self.out_proj = nn.Linear(args.d_inner, args.d_model, bias=False, device=device)
        self.reset_parameters()
    def reset_parameters(self) -> None:
        dt_min, dt_max = 1e-3, 1e-1
        device = self.dt_bias.device
        dtype = self.dt_bias.dtype
        dt = torch.exp(
            torch.rand(self.args.nheads, device=device, dtype=dtype)
            * (math.log(dt_max) - math.log(dt_min))
            + math.log(dt_min)
        )
        with torch.no_grad():
            self.dt_bias.copy_(torch.log(torch.expm1(dt)))
            self.A_log.copy_(
                torch.log(
                    torch.arange(
                        1, self.args.nheads + 1, device=device, dtype=self.A_log.dtype
                    )
                )
            )
            self.D.fill_(1.0)
    def forward(self, u: Tensor, h: InferenceCache | None = None):
        if h is not None:
            return self.step(u, h)
        A = -torch.exp(self.A_log)
        zxbcdt = self.in_proj(u)
        z, xBC, dt = torch.split(
            zxbcdt,
            [
                self.args.d_inner,
                self.args.d_inner + 2 * self.args.d_state,
                self.args.nheads,
            ],
            dim=-1,
        )
        dt = F.softplus(dt + self.dt_bias)
        xBC_t = rearrange(xBC, "b l d -> b d l")
        if u.shape[1] >= self.args.d_conv:
            conv_state = xBC_t[:, :, -self.args.d_conv :]
        else:
            conv_state = F.pad(xBC_t, (self.args.d_conv - u.shape[1], 0))
        xBC = silu(
            self.conv1d(xBC.transpose(1, 2)).transpose(1, 2)[:, : u.shape[1], :]
        )
        x, B, C = torch.split(
            xBC, [self.args.d_inner, self.args.d_state, self.args.d_state], dim=-1
        )
        x = rearrange(x, "b l (h p) -> b l h p", p=self.args.headdim)
        y, ssm_state = ssd(
            x * dt.unsqueeze(-1),
            A * dt,
            rearrange(B, "b l n -> b l 1 n"),
            rearrange(C, "b l n -> b l 1 n"),
            self.args.chunk_size,
            device=x.device,
        )
        y = y + x * self.D.unsqueeze(-1)
        y = rearrange(y, "b l h p -> b l (h p)")
        y = self.norm(y, z)
        y = self.out_proj(y)
        h = InferenceCache(conv_state, ssm_state)
        return y, h
    def step(self, u: Tensor, h: InferenceCache):
        assert u.shape[1] == 1, "Only one token can be decoded per inference step"
        zxbcdt = self.in_proj(u.squeeze(1))
        z, xBC, dt = torch.split(
            zxbcdt,
            [
                self.args.d_inner,
                self.args.d_inner + 2 * self.args.d_state,
                self.args.nheads,
            ],
            dim=-1,
        )
        h.conv_state.copy_(torch.roll(h.conv_state, shifts=-1, dims=-1))
        h.conv_state[:, :, -1] = xBC
        xBC = torch.sum(
            h.conv_state * rearrange(self.conv1d.weight, "d 1 w -> d w"), dim=-1
        )
        xBC += self.conv1d.bias
        xBC = silu(xBC)
        x, B, C = torch.split(
            xBC, [self.args.d_inner, self.args.d_state, self.args.d_state], dim=-1
        )
        A = -torch.exp(self.A_log)
        dt = F.softplus(dt + self.dt_bias)
        dA = torch.exp(dt * A)
        x = rearrange(x, "b (h p) -> b h p", p=self.args.headdim)
        dBx = torch.einsum("bh, bn, bhp -> bhpn", dt, B, x)
        h.ssm_state.copy_(h.ssm_state * rearrange(dA, "b h -> b h 1 1") + dBx)
        y = torch.einsum("bhpn, bn -> bhp", h.ssm_state, C)
        y = y + rearrange(self.D, "h -> h 1") * x
        y = rearrange(y, "b h p -> b (h p)")
        y = self.norm(y, z)
        y = self.out_proj(y)
        return y.unsqueeze(1), h
 def segsum(x: Tensor, device: Device = None) -> Tensor:
    if device is None:
        device = x.device
    T = x.size(-1)
    x = repeat(x, "... d -> ... d e", e=T)
    mask = torch.tril(torch.ones(T, T, dtype=torch.bool, device=device), diagonal=-1)
    x = x.masked_fill(~mask, 0)
    x_segsum = torch.cumsum(x, dim=-2)
    mask = torch.tril(torch.ones(T, T, dtype=torch.bool, device=device), diagonal=0)
    x_segsum = x_segsum.masked_fill(~mask, -torch.inf)
    return x_segsum
 def ssd(x, A, B, C, chunk_size, initial_states=None, device: Device = None):
    assert x.shape[1] % chunk_size == 0
    x, A, B, C = [
        rearrange(m, "b (c l) ... -> b c l ...", l=chunk_size) for m in (x, A, B, C)
    ]
    A = rearrange(A, "b c l h -> b h c l")
    A_cumsum = torch.cumsum(A, dim=-1)
    L = torch.exp(segsum(A, device=device))
    Y_diag = torch.einsum("bclhn, bcshn, bhcls, bcshp -> bclhp", C, B, L, x)
    decay_states = torch.exp(A_cumsum[:, :, :, -1:] - A_cumsum)
    states = torch.einsum("bclhn, bhcl, bclhp -> bchpn", B, decay_states, x)
    if initial_states is None:
        initial_states = torch.zeros_like(states[:, :1])
    states = torch.cat([initial_states, states], dim=1)
    decay_chunk = torch.exp(segsum(F.pad(A_cumsum[:, :, :, -1], (1, 0)), device=device))
    new_states = torch.einsum("bhzc, bchpn -> bzhpn", decay_chunk, states)
    states, final_state = new_states[:, :-1], new_states[:, -1]
    state_decay_out = torch.exp(A_cumsum)
    Y_off = torch.einsum("bclhn, bchpn, bhcl -> bclhp", C, states, state_decay_out)
    Y = rearrange(Y_diag + Y_off, "b c l h p -> b (c l) h p")
    return Y, final_state
 class RMSNorm(nn.Module):
    def __init__(self, d: int, eps: float = 1e-5, device: Device = None) -> None:
        super().__init__()
        self.eps = eps
        self.weight = nn.Parameter(torch.ones(d, device=device))
    def forward(self, x: Tensor, z: Tensor | None = None) -> Tensor:
        if z is not None:
            x = x * silu(z)
        return x * torch.rsqrt(x.pow(2).mean(-1, keepdim=True) + self.eps) * self.weight
 def silu(x: Tensor) -> Tensor:
    return x * torch.sigmoid(x)
--- a/pyproject.toml
+++ b/pyproject.toml
@@ -0,0 +1,13 @@
 [project]
 name = "test-diffusion"
 version = "0.1.0"
 description = "Add your description here"
 readme = "README.md"
 requires-python = ">=3.12"
 dependencies = [
    "einops>=0.7.0",
    "matplotlib>=3.8.0",
    "numpy>=1.26.0",
    "swanlab>=0.5.0",
    "torch>=2.2.0",
 ]
--- a/uv.lock
+++ b/uv.lock